Stabilization of carbamate esters



Sept. 27, 1960 G. w. AYERs ErAL STABILIZATION oF CARBAMATE EsTERs '2 Sheets-Sheet 1 Filed may 16, 1958 o mvENToRs GEORGE w. AYERs oom WILLIAM A. KREWER BY THOMAS W. MARTINEK LE ROI E.HUT HINGS WJ M ATTORNE Sept. 27, 1960 G. w. AYERs ETAL STABILIZATION oF CARBAMATE EsTERs 2 Sheets-Sheet 2 Filed vay 16, 1958 o om d oo. w s S n H .J w .w om.

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m .0E wmaor w m n ourwm Gm l @N I\s Md do@ `wO uw INVENTORS GEORGE W. AYERS E 'SH 'ww aanssaad OON WILLIAM A. KREWER United States STABILIZATION F CARBAMATE ESTERS Filed May 16, 195s, ser. No. 735,829

1s claims. (cl. 26o- 482) This invention relates to a method of stabilization of carbamate esters against decomposition during use, particularly when used as solvents inV selective extraction prcesses. More particularly, the invention relates to the discovery that incorporating small quantities of hydrochloric acid, phosphoric acid, acetic acid, ammonium chloride, ammonium dihydrogen phosphate, and ferric chloride with the carbamate ester solvents inhibits the decomposition and stabilizes the esters.

This invention also relates to the composition including certain carbamate esters containing a. sufficient amount of an inhibitor to prevent hydrolysis. The carbamate ester-inhibitor composition may contain from about 5.() to 50% by weightof water.

The preserving art has developed tothe point Where numerous inhibitors are known and used for the purpose of preventing polymerization and/ or oxidation of organic materials. For instance, various antioxidants are known which prevent the oxidation of carbon atomdouble bonds in organic esters. It has been discovered in accordance with this invention that carbamate esters of a broad class,k l ,p

to be described, can exhibit two types of break-down, namely, pyrolysis under conditions wherein an essentially anhydrous ester is subjected to elevated temperatures, and-V hydrolysis which occurs in the presence of Water during long-time usage, as for example, during storage or in a solvent extraction process. In accordance with this invention, it has been discovered that the second type of break-down can be inhibited by Vincorporating small quantities of certain inhibiting substances. f l

Accordingly, a primary object of this invention Yis tO provide a process for stabilizing carbamate esters against decomposition during use. i

Another object is to provide comprising certain carbamate esters and suiicient amounts of a decomposition inhibitor, or mixtures of same, to stabilize the carbamate esters.

Another object of the invention is to provide a method of solvent extraction employing as solvents vcertain car- `a composition of-matter wherein X and/or X are substituent groups which may broadly be hydrogen, alkyl groups, cycloalkyl groups, aryl groups, polar-substituted alkyl groups, polar-substituted aryl groups, and'heterocyclic groups and Y is a polar-substituted alkyl, aryl, alkaryl, aralkyl, or cycloalkyl group. More speciiica1ly,'X and/or X' may be selected substituents from the following groups: hydrogen, methyl, ethyl, propyl, isopropyl, butyl, isobutyl, tertiary butyl, amyl, is-oamyl, cyclopentyl, cyclohexyl, cyclolieptyL phenyl, tolyl, xylyl, hydroxymethyl, hydroxyethyl, hydroxypropyl, hydroxyisopropyl, hydroxybutyl, hydroxyisobutyl, hydroxyamyl, hydroxyisoamyl, cyanomethyl, cyanoethyl, cyanopropyl, cyanobutyl, cyanoisobutyl, cyanoamyl, cyanoisoamyl, methoxymethyl, methoxyethyl, methoxypropyl, methoxyisopropyl, methoxybutyl, methoxyisobutyl, methoxyamyl, methoxyisoamyl, acetamidoethyl, acetamidopropyl, acetamidoisopropyl, acetamidobutyl, acetamidoisobutyl, acetamidoamyl, carboethoxyethyl, carboethoxypropyl, carboethoxyisopropyl, carboethoxybutyl, andcarboethoxyamyl. Additional specific substituent groups include nitrophenyl, i.e., 4-nitrophenyl, cyanophenyl, i.e., 4-cyanophenyl, morpholinyl, pyridyl and piperidinyl and the like.

Y in the above formula is a polar-substituted alkyl, aryl, alkaryl, aralkyl or cycloalkyl group including the aorementioned hydroxyalkyL, cyanoalkyl, methoxyalkyl, acetimidoalkyl and carboethyoxyalkyl groups in relation to the denition of X and X. Other Ypolar groups that may be used in place of or 4along with the foregoing are the iluoro, chloro, iodo and bromo groups.

Carbamate esters of the foregoing class are used in a 'number of processes in which the stability of the esters over .an extended period of timel is otjprime importance, particularly where the esters aresubject to temperatures higher than ambient temperaturesmlor example, -hynrdroxyethyl dimethylcarbamate is--an excellent solvent-ex- ZODB.

bamate esters wherein the decomposition of the carbamate f esters during use in the extraction stage, or during recovery from the extract or ranate phase, or during other processes involving conditions conducive to decomposition, is prevented by maintaining or adding one or more inhibitors thereto. K

These and other objects will be described or become apparent as the description of the invention proceeds.

Figures 1, 2, 3 and 4 are graphic representations of the relative eiectiveness of various materials tested, using time in hours as the abscissa and carbon dioxide pressures as the ordinates.

The carbamate esters with which the present invention linds utility are esters of carbamic acid, or N-substituted carbamic acids, in which the ethyl group contains at least one polar constituent. These compounds may be represented bythe general formula:

traction agent for aromatic hydrocarbons. This solvent is generally used with small quantities of water for the purpose of increasing the selectivity and facilitating phase separation. In the practice ofv solvent extraction, the solvent'is separated from the extractlfand raihnate phases by the application of Water dilution and/or the use of an auxiliary non-polar solvent, which processes are followed byA heating steps, including distillation or flash vaporization, wherein the solvent in admixture withfwater is heated to temperatures Vabove F. and v`ashigh as the boiling point ofthe particular esters. .The .solvent receovered from such processing is recycled to the primary extraction Since the various steps of solvent extraction yand recovery of solvent are known in the art, the invention herein does not relate to the use of the'ester in any Yparticular solvent-extraction process. The invention is, accordingly, intended to cover any use of the esters wherein decomposition may occur.

At ambient temperatures, the hydrolysis of -hydroxyethyl dimethylcarbamate 1in the presence of about 1A of its volume of water is practically negligible, even where the contact is over extended periods. At temperatures above approximately 178 F., the hydrolysis reaction rate increases rapidly for this individual ester. In accordance with the invention, it has been found that a mixture of a carbamate ester, as for example -hydroxyethyl dimethylcarbamate, and a small amount, that is, 0.05 to 1.0%, of hydrochloric acid, phosphoric acid, ammonium chloride, ammonium dihydrogen phosphate, and ferric chloride exhibits a greatly ydecreased hydrolysis rate.

Pyrolysis of -hydroxyethyl dimethylcarbamate at elevated temperatures results in the production of dimethylammonium dimethylcarbamate, ethylene glycol, and dimethylaminoethanol. This reaction takes place at a very sloW rate and for all practical purposes may be 4 vals of time. In some instances the ester residue was titrated potentiometrically with hydrochloric acid to determine the amount of dimethylammonum dimethylcarbamate formed, and hence the percent of hydrolysis of the ester according to the equation,

2-hydroxyethyl dimethylcarbamate (CHQZNC O ONHa(CHa)2-|C Orl-ZBO CHZCHQOH dimethylammonium ethylene glycol dimethylcarb amate The results are shown in the following table.

TABLE I Ejject of added substances on the hydrolysis of Z-hydroxyethyl dmethylcarbamate [Added substance was heated at 100 C. in a closed system with 2-hydroxyethy1 dimethylcarbamate containing 20% water and pressure rise Was used as a measure of hydrolysis; in some cases the residue was titrated to given an amount of dimethylammonium dimethylcarbamate formed and from this the percent 2-hydroxyethyl dimethylcarbamate hydrolyzed was obtained] Percent Percent by Wt. Solubility of added Pressure rise hydro- Run No. Added substance of added substance in (mm.Hg) after lyzed substance Carbamate 6 hrs. after 6 hrS.

L None (straight 2-hydroxyethyl dimethylcarbamate) 221 (3.5 hrs.) 0. 58

(A) STABILIZERS (2hydroxyethyl dlmethylcarbamate after addition of HC1 and redistillation). Hydrochloric acid (37% solution of HC1 in water).-.. 0. 2 qnlnhlo Phosphoric acid (85% 1131304) 1.0 do Acetic acid (CHaCOOH) 0.2 -.-do Ammonium dihydrogen phosphate ((NHDHzPOi) 1.0 Partially soluble Ammonium chloride (NHiCl) 1.0 do Ferrie chloride (FeOl3-6H2O) 1.0 do

(B) SUBSTANCES SHOWING LITTLE OR NO STABILIZATION Boric acid (HSBOa Dimethylammonium chloride ((CH:)2N

Ammonium oxalate ((NH4)2C204.H2O) Urea (NHZCONHQ Thiourea (NHZOSNEM) Triethanolamine ((HOCHiiCHiOaNL. Ethylene carbonate Sodium metaphosphate (Na4P4O1z) Ferrous sulfate (FeSO4.7H2O) Sodium oxalato (Na2C2O4.4HnO) Ammonium sulfate ((NHmSOr) tively by determining the pressure increase in the system due to release of carbon dioxide. The actual hydrolysis reaction and its products can be measured quantitatively by potentiometric titration yof the mixture. After an individual test, the dimethylammonium dimethylcarba-mate formed during the hydrolysis is readily titrated with hydrochloric acid. Materials having a definite alkaline reaction cannot be evaluated by this method and appear to be inoperative.

In order to demonstrate the invention, a number of substances were evaluated as possible lretarding agents for the hydrolysis `of -hydroxyethyl dimethylcarbamate. These tests Were conducted by placing 25 grams of aqueous lB-hydroxyethyl dimethylcarbamate, containing 20% by Weight of water, and 0.2 to 1.0% by Weight of the prospective retarding agent in a glass flask immersed in a bath of boiling Water. The glass flask containing the ester and additive was sealed to the bottom of a watercooled vertical condenser and the exit end of the condenser was in turn sealed to a mercury manometer. During the course of the experiments, the pressure increases in the system were noted and recorded at definite inter- Examples of polar-substituted carbamic acid esters coming Within the scope of this invention are: Z-hydroxyethyl N-methyl carbamate, 2-hydroxyethyl N-ethyl 'carbarnate,V Z-hydroxyethyl N-i-propyl carbamate, Z-hydroxyethyl N,Ndimethy1 ca-rbamate, 2-chloroethyl N-methyl carbamate, 2-chloroethyl N-ethyl carbamate, 2-chloroethyl N-isopropyl carbamate, 2-chloroethyl N,Ndimethyl carbamate, 3-chloropropyl N-methyl carbamate, 3-chloropropyl N-ethyl carbamate, 3-chloropropyl Nisopropyl ca-rbam'ate, 3-chloropropyl N,Ndimethyl carbamate, 2 iodoethyl N-methyl carbamate, 2-iodoethyl N-ethyl carbamate, 2-iodoethyl N-i-propyl carbamate, 2-iodoethyl N,Ndimethyl carbamate, 2-fluoroethyl N-methyl carbamate, 2-uoroethyl N-ethyl ca-rbamate, Z-iluoroethyl N-i-propyl carbamate, 2uoroethyl N,Ndimethyl carbamate, 2-bromoethyl N-methyl carbamate, Z-bromoethyl N-ethyl carbamate, 2-bromoethyl N-i-propyl carbamate, 2-bromoethyl N,Ndimethyl .carbamate, hydroxyphenyl N-methyl carba-mate, hydroxyphenyl N-ethyl carbamate, hydroxyphenyl N-isopropyl lcarbamate, hydroxyphenyl N, N-dimethyl carbamate and ohlorophenyl N-methyl carbamate.

The physical properties of certain of these carbamates are shown in the following table:

TABLE n Physical properties of carbamates tested Br. v13.11.- CarbarnateY (O./mm. Y. (calcd) Ref. Index v f Hg) (o.@76o (me 04D) z-hydroxyethyi 1st-methyl. g.; 107-108/1. 2 275 1. 4516 z-hydrpxyethyi Nethy1 rasgos/sH .y 275 1.4532 2-hydroxyethyl N-ifpropyl 114-122/0.'5 335 1.4520 2-hydroxyethy1N,N-dlmethyl.` 182-86/1f2 f' 24,5v 1.4497

The -invention Yfinds particular application inY theuse of the polar-substituted carbarnic `lacid esters in .liquidliquid or. liquid-vapor solvent extraction systems wherein the objective is to extract a predominance of the aromatic hydrocarbons or alkyl-substituted homologues from ad mixture with non-aromatic hydrocarbons. For this purpose, the -feed hydrocarbon containing the desired aromatics is treated in a single tower, or in a series of towers, with one or more successive portions, or is treated continuously with the carbamate solvent. The portions of solvent or the solvent-to-feed ratio in the successive or continuous ltreatments may vary in accordance with the extent of extraction sought. The process may be batchwise, or countercu-rrent 110W 4in a vertical tower may be used..

In order to illustrate this aspect of the invention, the feed hydrocarbon containing aromatics is introduced into a primary extraction tower wherein the feed passes in counter-current contact with a carbamate solvent which contains an hydrolysis-inhibiting additive,according to, this invention. This treatment results in a rainate containing a small amount of solvent and a predominance of the paratlinic hydrocarbons, and an extract phase containing solvent and a high proportion of aromatics. The raffinate phase is treated to water Washing in order toremove the small amount of carbamate solvent therefrom land the solvent so recovered is recycled to the primary extraction tower. The extract phase may be treated by distillation in order to remove the solvent. About 5 to 20% by weight of water is used with the solvent during the extraction. Accordingly, the distillation results in` an overhead of semi-purified aromatichydrocarbons and a bottoms fraction which comprises the solvent-water mixture to be recycled to the primary ext-raction. This bottoms fraction is tested to make sure it contains sufficient hydrolysis inhibitor, and then is recycled to the primary extraction tower, with or without any adjustment of the Water content necessary for the degree of extraction that is to be accomplished. The `extract phase may also be treated with a high-boiling parainic hydrocarbon containing no contaminating unsaturated hydrocarbons to dissolve the aromatics and produce a denuded solvent phase. Following this treatment, the `denuded solvent phase is combined with the hydrolysis inhibitor in accordance with this invention, and likewise recycled to the primary extraction tower.

In order to 'further demonstrate the invention with a non-limiting example, an -aromatic feed consisting of 32% by volume of benzene and 68% by volume of paraflins is treated in an extraction tower with a solvent consisting of 80%.by volume of Z-hydroxyethyl N,Ndimethylcar bamate and by volume of water using the following operating conditions -in the tower:

lExtraction tower operating conditions:

Solvent/feed ratio.. 6/ 1 Reflux/feed ratio 1.7/1 Solvent rate gal. p. hr-.. 3.0 Feed rate gal. p. hr..- 0.51

`"Reflux rate ga1 p. hr-- 0.88

The extract is treated to distillation,`with Water reflux, at a still-pot temperature of 229 F. The paraflinic product is washed with water to remove the trace amount of solvent that is present. The solvent is treated with sufficient phosphoric acid to substantially eliminate hydrolysis ofthe solvent during the extraction step. The following product rates and compositions are obtained:

Product rates and compositions:

' .B`e11-ze1 1 e ..1 j 0.16 gal. p. hr.

` 99% by vol. benzene. 1% by vol. parafns. 0.35 gal. p. hr. 1% by vol benzene. v 99% by vol. parain.

When applying the method of this invention to a solvent-extraction process, the technique of preserving the solvent by `means of an inhibitor to ret-ard hydrolysis is 'applicable to recovery of economic amounts of aromatics, including benzene and alkyl homologues thereof such as toluene, xylenes, that is, o-xylene, m-xylene and -p-xylene, and also ethyl benzene. Such feed materials as petroleum distillates, naphthas, gasoline, kerosine, fuel oil fractions and gas oil fractions may also be subjected to solvent extraction with the carbamate esters disclosed herein while applying the method of stabilization which constitutes this invention. One suitable feed is the class of products known in the art at catalytic reformates which contain desirable quantities of aromatics; Catalytic reforrnates are obtained by treating naphthas to reforming, dehydrogenation, hydrocracking and de'- hydrocyclization at temperatures ranging from 850 F. 'to- 1000 F. Withpressures up to about 500 p.s.i.g. in the presence of a metal-containing catalyst,

As a more specific illustration, catalytic reformates obtained las a result of the treatment of a virgin naphtha .(BR 175 F.-400 F., API gravity 50 to 60). with a platinum-alumina catalyst at 875 F. to 975 F. and pressures ranging from 200 to 500 p.s.i.g. may be used. Reformates so produced contain from about 30 to 55 vol. percent of aromatics and constitute a preferred feed for the present process. For example, reformates produced by reforming a 200-4,00 F. virgin naphtha lat about V930 F. and 325 p.s.i.g. in the presence of a catalyst --comprising about 0.1 wt. percent of platinum on an alumina base, are representative. In general, t-hese reformates have la boiling range of about to 400 F., en API gravity of 40 to 50, and an aromaticY content of 45-55 volume percent. A particularly suitable reformate is obtained by subjecting a charge naphtha having -a boiling range of 178 F. to 389 F., an API gravity of 59.1, a RON clear, of 44.6, a RON-i-O TEL of 71.4 and containing 0.01% sulfur, about 91.0 vol. percent of paraifins and n-aphthenes, 1.0 vol. percent olefins, and 8.0 vol. percent aromatica to reforming at about 930 F., to produce a product having an API Parain product r' l gravity of 49.2, and IBP of 128 F.- and EBP of 405 Aromatics in reformate feed Aromatic: Vol. percent Benzene 4.19 Toluene 13.1 Mixed Xylene 'and ethyl benzene 16.51 C9 and heavier 1 17.2

In general, the method of stabilization by the addition of one or more of a selected group of substances, namely, acetic acid, phosphoric acid, hydrochloric acid,

monium dihydrogen phosphate, ammonium chloride, ferr-ic chloride, and mixtures thereof, is `applic-able to the Wide range of conditions under which the carbamate esters disclosed herein may be used. Hydrolysis and other decomposition of these carbamate esters proceeds more rapidly at elev-ated temperatures and is less of a problem at low temperature. In gener-al, these carbarnate esters require stabilization at temperatures from about 25 C. to 190 C. The process of this invention nds particular application during solvent extraction where temperatures ranging from `about C. to as high as 80 C. lare used, with pressures ranging yfrom atmospheric to or 15 p.s.i.g.

The method of lstabilization of the invention has been demonstrated by a number of tests which were conducted under accelerated conditions. Accordingly, a time period of about 6 hours, as shown on the graphs, represents about 6 weeks time of .actu-al use as during an extraction process. Also, the 50 mm. Hg on the pressure scale of the Igraphs represents about the maximum amount of decomposition that can be tolerated in any given situation. Among the vario-us materials tested, only those which prevent the pressure of escaping carbon dioxide from rising to a value about SO/mrn. of mercury in ya period of labout 6 hours are to be considered as functioning properly to inhibit the decomposition. As seen from the graphs, certain of the materials lose their effectiveness in a relatively short time. Also, the informationgiven herein emphasizes the fact that one cannot predict just how a given material will yfunction in this environment.

The following table illustrates specic examples of compositions that may be formulated in accordance with this invention:

2-hydroxyethyl N ,N-dimethyl carbamatc. ammonium dihydrogen phosphate Water {Zhydroxyethyl N-i-propyl carbarnate.

phosphoric acid. hydrochloric acid. water {Z-hydroxyethyl N-N-dimethyl carbamate.

phosphoric acid hydrochloric acid. Water Although the inhibitors of this invention may be used to form a stable composition with the described carbamate esters with or without between about 5.0 .to 50% by weight of water, or may be lused .to prevent decomposition at any desired point in a processing system, the preferred application is during use :as a selective solvent or while said selective solvent .is being subjected to recovery. For .the various purposes described herein, .the inhibitors may be added to .the carbamate esters in .the prescribed amounts before use, `during storage, or `added con-tinuously or intermittently 4before or during the subjection of the carbamate ester to .decomposition conditions, particularly hydrolysis conditions. Decomposition by way of .the hydrolysis reaction may `occur lin systems wherein the car-barnate esters are used without Water because of leaks in steam` coils .and the .diicult-ies always experienc-ed in excluding water from .a system. Accordingly, the invention may be applied where the carbamate ester are used under ostensibly anhydrous conditions.

3. The method in accordance with claim 1 in which thevsubstance is phosphoric acid.

4. The method in accordance with claim 1 in whichv the substance is hydrochloric acid.

5. The method in accordance with claim 1 in which the substance is ammonium dihydrogen phosphate.

6. The method in accordance with claim 1 in which the substance is ammonium chloride.

7. The method in `accordance with claim 1 in which the substance is ferrie chloride.

8. The method of stabilizing carbamate esters otE the general formula wherein X and X :are the same or diierent substituent radicals selected from the group consisting of hydrogen, alkyl, cycloalkyl, aryl, .alkaryl, aralkyl, polar-substituted alkyl, polar-'substituted aryl and heterocyclic radicals, and Y is selected trom the group of polarsubstituted alkyl, polar-substiuted aryl, polar-substituted .alkaryl, polarsubstituted .ai-.alkyl and polar-substituted cycloalkyl radicals against hydrolytic decomposition which comprises adding theretol about 0.05 to 5.0 percent by Weight of a substance selected trom the 'group consisting of acetic acid, phosphoric acid, hydrochloric acid, ammonium dihydrogen phosphate, ammonium chloride, ferrie chloride, and mixtures thereof.

9. The method -in accordance with claim 8 in which said carbamate ester is 2-hydroxyethyl N-N-dimethyl carbamate.

10. The method in accordance with 8 in which said carbamate tester is Z-'hydroxyethyl N-methy-l carbamate.

11. The method in accordance with claim 8 in which said carbamate tester is Z-hydroxyethyl N-isopropyl carbamate.

12. The process of separating aromatic hydrocarbons and homologues thereof from non-:aromatic hydrocarbon mixtures containing same which comprises contacting said mixture with .a pol-ar-N- substituted carbarnarte solvent in an extracting treatment in the presence of water, separating the composite mixture into two components consisting of :an `extract phase and a raffinate phase, separating non-aromatic hydrocarbons and solvent from said rainate phase, separating aromatic hydrocarbons `and solvent from said extract phase, while maintaining .about 0.05 to 5.0 percent by weight of la substance selected from the -group consisting of acetic aci-d, phosphoric acid, hydrochloric acid, ammonium dihydrogen phosphate, ammonium chloride, ferrie chloride, `and mixtures thereof in solution in said solvent to prevent hydro-lytic decomposition of said solvent.

13. The method 4in accordance with claim 12 in which .the solvent contains about 5 to 20% .by weight of water.

14. The method in. :accordance claim 13 in which said solvent .is Z-hydroxyethylN,N-dimethy1 carbamate.

15. The method in .accordance with claim 13 in which said carbamate ester `is 2-hydroxyethyl Namethyl carbamate.

16. The method in `accord-ance with claim 13 in which said carbamate ester is Z-.hydroxyethyl N-.isopropyl carbarnate.

1.7 In the process of sepamating aromamic hydrocarbons -and homologues thereof from non-aromatic hydrocaribons wherein a polaI-N-substituted canbamate ester. is used as the selective solvent to form an extract phase and a -raiiinate phase and said solvent is recovered from said phases, the method of peventing the hydrolytic decomposition of said solvent dum-ing said recovery which comprises maintaining a sufficient :amount of la substance selected from the group consisting of .acetic acid, phosphoric acid, hydrochloc acid, ammonium dihydrogen phosphate, ammonium chloride, ferrie chloride, and mixtures thereof, in said solvent.

18. A composition of matter comprising a major portion of va ploar-N-substituted carbamaite ester and a small amount of fa substance selected trom the igroup consisting of acetic acid, phosphoricy acid, hydrochloric acid, ammonium idihydrogen phosphate, ammonium chloride, feriic chloride, and mixtures thereof.

References Cited in the le of this patent UNITED STATES PATENTS 2,333,917 Chris-t et al. ..-i Nov. 9, 1943 2,386,927 Boyd Oct. 16, 1945 2,594,044 Doder Apr. 22, 1952 2,617,784 Slocombe et al. Nov. 11, 1952 2,620,349 Slocombe Dec. 2, 1952 2,666,752 Gmummimt et al Jan. 19, 1954 2,692,874

Langenak Oct. 26, 1954 

1. THE METHOD OF STABILIZATION OF N-SUBSTITUTED ALKYL CARBAMATES AGAINST HYDROLYTIC DECOMPOSITION WHICH COMPRISES ADDING THERETO ABOUT 0.5 TO 5.0 PERCENT BY WEIGHT OF A SUBSTANCE SELECTED FROM THE GROUP OF ACETIC ACID, PHOSPHORIC ACID, HYDROCHLORIC ACID, AMMONIUM DIHYDRO- 